Immiscible fluid displacement: From pore doublets to porous media

Authors

  • Zhongzheng Wang* School of Mechanical, Medical and Process Engineering, Queensland University of Technology, QLD 4001, Australia (Email: zhongzheng.wang@qut.edu.au)

Abstract

Understanding multiphase flow in porous media is essential for diverse engineering applications, from large-scale carbon geosequestration to small-scale fuel cells. Poredoublet models, despite their geometrical simplicity, offer a powerful framework to study the complex interplay between capillary and viscous forces during multiphase flow. This work revisits some recent advances in the understanding of immiscible fluid displacement processes provided by pore-doublet studies, and highlights their ability to capture key interfacial phenomena such as Haines jumps and to map displacement regimes through phase diagrams. While these models do not capture the full heterogeneity of real porous systems, they often exhibit strong agreement with larger-scale observations. Recent advances in microfluidics fabrication techniques further enhance the capability and efficiency of using pore-doublet models to investigate immiscible displacement processes. Several promising research directions for extending pore-doublet approaches are identified.

Document Type: Perspective

Cited as: Wang, Z. Immiscible fluid displacement: From pore doublets to porous media. Capillarity, 2025, 15(1): 1-3. https://doi.org/10.46690/capi.2025.04.01

Keywords:

Pore doublets, multiphase flow, porous media

References

Al-Housseiny, T. T., Hernandez, J., and Stone, H. A. Preferential flow penetration in a network of identical channels. Physics of Fluids, 2014, 26(4): 042110.

Chatzis, I., Dullien, F. Dynamic immiscible displacement mechanisms in pore doublets: Theory versus experiment. Journal of Colloid and Interface Science, 1983, 91(1): 199-222.

Datta, S. S., Battiato, I., Fernø, M. A., et al. Lab on a chip for a low-carbon future. Lab on a Chip, 2023, 23: 1358-1375.

Dudukovic, N. A., Fong, E. J., Gemeda, H. B., et al. Cellular fluidics. Nature, 2021, 595(7865): 58-65.

Gu, Q., Liu, H., Wu, L. Preferential imbibition in a dual permeability pore network. Journal of Fluid Mechanics, 2021, 915: A138.

Haines, W. B. Studies in the physical properties of soil. v. the hysteresis effect in capillary properties, and the modes of moisture distribution associated therewith. The Journal of Agricultural Science, 1930, 20(1): 97-116.

Heinemann, N., Alcalde, J., Miocic, J. M., et al. Enabling large-scale hydrogen storage in porous media-the scientific challenges. Energy & Environment Science, 2021, 14: 853-864.

Liu, F., Wang, M. Phase diagram for preferential flow in dual permeable media. Journal of Fluid Mechanics, 2022, 948: A19.

Måløy, K. J., Furuberg, L., Feder, J., et al. Dynamics of slow drainage in porous media. Physical Review Letters, 1992, 68: 2161-2164.

Moebius, F., Or, D. Interfacial jumps and pressure bursts during fluid displacement in interacting irregular capillaries. Journal of Colloid and Interface Science, 2012, 377(1): 406-415.

Moura, M., Måløy, K. J., Flekkøy, E. G., et al. Intermittent dynamics of slow drainage experiments in porous media: Characterization under different boundary conditions. Frontiers in Physics, 2020, 7: 217.

Primkulov, B. K., Zhao, B., MacMinn, C. W., et al. Avalanches in strong imbibition. Communications Physics, 2022, 5(1): 52.

Shan, F., Chai, Z., Shi, B., et al. Optimal displacement of immiscible two-phase fluids in a pore doublet. Physics of Fluids, 2023, 35(5): 053332.

Sun, Z., Santamarina, J. C. Haines jumps: Pore scale mechanisms. Physical Review E, 2019, 100: 023115.

Szulczewski, M. L., MacMinn, C. W., Herzog, H. J., et al. Lifetime of carbon capture and storage as a climate change mitigation technology. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109(14): 5185-5189.

Wang, Y. D., Meyer, Q., Tang, K., et al. Large-scale physically accurate modelling of real proton exchange membrane fuel cell with deep learning. Nature Communications, 2023, 14(1): 745.

Wang, Z., Ong, L. J. Y., Gan, Y., et al. Porofluidics: deterministic fluid control in porous microfluidics. Lab on a Chip, 2024, 24: 4050-4059.

Wang, Z., Sun, R., Gan, Y., et al. Controlled Haines jumps in a dual-channel multiphase system: inferring fluid properties from the dynamics of interface motion. Journal of Fluid Mechanics, 2025, 1002: A40.

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Published

2025-04-08

Issue

Vol. 15 No. 1 (2025): April (In Progress)

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Articles

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